CN108367741A - Electron gas dynamic formula brake apparatus with the pressure adjusting module being connect with two compressed air supply systems by two check-valves - Google Patents
Electron gas dynamic formula brake apparatus with the pressure adjusting module being connect with two compressed air supply systems by two check-valves Download PDFInfo
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- CN108367741A CN108367741A CN201680071597.6A CN201680071597A CN108367741A CN 108367741 A CN108367741 A CN 108367741A CN 201680071597 A CN201680071597 A CN 201680071597A CN 108367741 A CN108367741 A CN 108367741A
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- Prior art keywords
- compressed air
- valve
- air supply
- pressure
- supply system
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60T—VEHICLE BRAKE CONTROL SYSTEMS OR PARTS THEREOF; BRAKE CONTROL SYSTEMS OR PARTS THEREOF, IN GENERAL; ARRANGEMENT OF BRAKING ELEMENTS ON VEHICLES IN GENERAL; PORTABLE DEVICES FOR PREVENTING UNWANTED MOVEMENT OF VEHICLES; VEHICLE MODIFICATIONS TO FACILITATE COOLING OF BRAKES
- B60T8/00—Arrangements for adjusting wheel-braking force to meet varying vehicular or ground-surface conditions, e.g. limiting or varying distribution of braking force
- B60T8/32—Arrangements for adjusting wheel-braking force to meet varying vehicular or ground-surface conditions, e.g. limiting or varying distribution of braking force responsive to a speed condition, e.g. acceleration or deceleration
- B60T8/321—Arrangements for adjusting wheel-braking force to meet varying vehicular or ground-surface conditions, e.g. limiting or varying distribution of braking force responsive to a speed condition, e.g. acceleration or deceleration deceleration
- B60T8/3255—Systems in which the braking action is dependent on brake pedal data
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60T—VEHICLE BRAKE CONTROL SYSTEMS OR PARTS THEREOF; BRAKE CONTROL SYSTEMS OR PARTS THEREOF, IN GENERAL; ARRANGEMENT OF BRAKING ELEMENTS ON VEHICLES IN GENERAL; PORTABLE DEVICES FOR PREVENTING UNWANTED MOVEMENT OF VEHICLES; VEHICLE MODIFICATIONS TO FACILITATE COOLING OF BRAKES
- B60T13/00—Transmitting braking action from initiating means to ultimate brake actuator with power assistance or drive; Brake systems incorporating such transmitting means, e.g. air-pressure brake systems
- B60T13/10—Transmitting braking action from initiating means to ultimate brake actuator with power assistance or drive; Brake systems incorporating such transmitting means, e.g. air-pressure brake systems with fluid assistance, drive, or release
- B60T13/66—Electrical control in fluid-pressure brake systems
- B60T13/68—Electrical control in fluid-pressure brake systems by electrically-controlled valves
- B60T13/683—Electrical control in fluid-pressure brake systems by electrically-controlled valves in pneumatic systems or parts thereof
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- Engineering & Computer Science (AREA)
- Transportation (AREA)
- Mechanical Engineering (AREA)
- Braking Systems And Boosters (AREA)
- Valves And Accessory Devices For Braking Systems (AREA)
- Regulating Braking Force (AREA)
Abstract
The present invention relates to a kind of electron gas dynamic formula brake apparatus (1),It has the first electron gas dynamic formula pressure adjusting module (6),The first electron gas dynamic formula pressure adjusting module has the first relaying valve gear (22a),The first entrance/discharge solenoid valve combination (16a) of the first relaying valve gear (22a) of pneumatically control,The first supply interface (14a) for entering valve (18a) and connecting of (16a) is combined with the first supply input terminal (52a) of the first relaying valve gear (22a) and with entrance/discharge solenoid valve,Wherein,First supply interface (14a) of first pressure adjustment module (6) and two mutually independent compressed air supply systems (40,46) at least one,First compressed air supply system (40) and third compressed air supply system (46) connection.The present invention is arranged,First supply interface (14a) is connect with the first compressed air supply system (40) by least one first check-valve (42) and is connect with third compressed air supply system (46) by least one second check-valve (48),Wherein,The check-valves (42,48) it respectively includes valve closure member (58) of at least one spring force pressure by least one spring element (54) to valve seat (56) and allows from compressed air supply system (40 along conducting direction when valve closure member (58) is lifted from valve seat (56),46) each or simultaneously from two compressed air supply systems (40,46) to the compressed air flowing of the first supply interface (14a),However it is prevented from the first supply interface (14a) to described two compressed air supply systems (40 along cut-off direction when valve closure member (58) compresses valve seat (56),46) one of or to two compressed air supply systems (40,46) compressed air is flowed and is flowed from the first compressed air supply system (40) to third compressed air supply system (46) or from third compressed air supply system (46) to the compressed air of the first compressed air supply system (40).
Description
Technical field
The present invention relates to a kind of electron gas dynamic formula brake apparatus of preamble according to claim 1, the electron gases
It includes that dynamic formula brake apparatus, which has the first electron gas dynamic formula pressure adjusting module, the first electron gas dynamic formula pressure adjusting module,
One relaying valve gear, the first entrance/discharge solenoid valve combination for pneumatically controlling the first relaying valve gear, the first standby electricity
Magnet valve, the first pressure sensor being connect with the first working outputs of the first relaying valve gear and the first control electronics
Device, the first control electronic device control first entrance/discharge solenoid valve combination and the described first spare solenoid valve
And the signal for representing the pressure on first working outputs is received to adjust first on first working outputs
Brake pressure;The electron gas dynamic formula brake apparatus has the first supply input terminal and the first pressure with the first relaying valve gear
The the first supply interface connected into valve of power adjustment module combined with entrance/discharge solenoid valve, wherein the first relay valve fills
The first working outputs set are connect with the working interface of first pressure adjustment module, the working interface and at least one pneumatic type
Checking cylinder directly or indirectly connects, and wherein, the first supply interface of first pressure adjustment module and two it is mutual indepedent
At least one of compressed air supply system compressed air supply system, the first compressed air supply system and third compression
Air supply device connects.
Background technology
Such electron gas dynamic formula brake apparatus is for example as known to WO 01/08953A1.There, the single channel pressure of front axle
Power adjustment module is by being configured to select the switching valve of high threshold either by front axle compressed air supply system or by additional
Supplementary compressed air feeding mechanism is supplied with compressed air.Therefore, if one of these compressed air supply systems failure or
One of these compressed air supply systems of person are adjusted to the compressed air feeding pipe leakage between switching valve, then single channel pressure
Module is always still provided with compressed air by the supply circuit not being involved accordingly.However, it has been found that such switching valve is not
It always reliably works and they can especially occupy undefined interposition state.
Invention content
In contrast, the task of the present invention is further research and develop the electron gas dynamic formula system of type stated above in this way
Dynamic device so that it more reliably works.
According to the present invention, which is solved by the feature of claim 1.
Arranged according to the present invention, the first supply interface is filled by least one first check-valve and the supply of the first compressed air
Set connect and connect with third compressed air supply system by second check-valve, wherein the check-valves respectively include to
A few spring force pressure by least one spring element supports the valve closure member of valve seat and is lifted from valve seat in valve closure member
When allow to be flowed to the compressed air of the first supply interface from two compressed air supply systems each along conducting direction, so
And it is prevented from the first supply interface to two compressed air supply systems along cut-off direction when valve closure element compresses valve seat
It one or is compressed to the compressed air flowing of two compressed air supply systems and from the first compressed air supply system to third
Air supply device is flowed from third compressed air supply system to the compressed air of the first compressed air supply system.
In other words, check-valves only allows the supply interface from two compressed air supply systems to first pressure adjustment module
Flowing, however between not allowing two compressed air supply systems or from supply interface to a compressed air supply system or
To the flowing in two compressed air supply systems.Here, those skilled in the art can select the bullet of check-valves as desired
The spring rate of spring element, so that such check-valves is switched to when there is the pressure difference limited between two interface
It is connected in the state of position, in the conducting position state, the two interfaces are connected with each other, and are otherwise just switched to cut-off position state by spring force
In.
By these measures, the compressed air feeding pipe between one of described compressed air supply system and supply interface
In or one of the compressed air supply system in leakage do not lead to the failure of involved brake circuit, to obtain such as existing
Start such compressed air supply redundancy in the WO 01/08953A1 referred to.
On the other hand, the switching valve that such, spring pre-tightening check-valves ratio such as uses in WO 01/08953A1 is more
It safely runs, so that compressed air supply redundancy is more reliable.Especially, the supply of first pressure adjustment module connects
Mouth can also simultaneously be supplied by the compressed air from two compressed air supply systems, this is equally and WO 01/
The difference of switching valve in 08953A1, in the prior art, only one of these compressed air supply systems can with it is preceding
The supply interface of the single channel pressure adjustment module of axis connects.
It can realize the present invention's provided in the independent claim by the measure enumerated in the dependent claims
Advantageous extension and improvement.
According to a preferred embodiment, the first pressure adjustment module is the front axle in front axle service brake circuit
Pressure adjusting module, wherein at least two Pneumatic brake cylinders of the working interface and front axle directly or indirectly connect,
In, first compressed air supply system is the front axle compressed air supply system in front axle service brake circuit.First
Brake pressure is then front axle brake pressure.
According to the extension of the preferred embodiment, the first electron gas dynamic formula pressure adjusting module and the second electron gas dynamic formula
Pressure adjusting module is mounted on together as structural unit in binary channels pressure adjusting module.
Second pressure adjustment module is preferably the rear axle pressure adjusting module in rear axle service brake circuit, wherein institute
At least two Pneumatic brake cylinders of the second working interface and rear axle of stating second pressure adjustment module directly or indirectly connect.
Because such binary channels pressure adjusting module is generally centrally arranged or is arranged in rear axle region, supplied in compressed air
It answers between device and binary channels pressure adjusting module or in the binary channels pressure adjusting module and before being arranged on front axle
Compressed air line relatively long, with relatively large pipe volume is obtained between axis checking cylinder.The relatively large pipeline
The hiding danger of volume is:When air requirements become larger suddenly, for example, in the scope braked completely, in the relatively long pressure
Enough air capacity or air pressure cannot be provided in solenoid road.However, because by described two check-valves cause ground, always from
Two compressed air supply systems, i.e. the first compressed air supply system and third compressed air supply system concurrently give first
The supply interface of pressure adjusting module provides compressed air, so compressed air supply amount ratio is only being supplied by a compressed air
It is big when unit feeding compressed air, so as to compensate disadvantage stated above.Then, more particularly to each service brake
Circuit (front axle service brake circuit, rear axle service brake circuit) realize combination formula, each tool, and there are one single channel pressures to adjust
The binary channels pressure adjusting module of module has arrangement placed in the middle or close to rear axle, but disadvantage not stated above.
Here, the especially complete circuit of two single channel pressure adjustment modules of the binary channels pressure adjusting module separates
, i.e., it is the relaying valve gear that is combined, divided with separated compressed air feedway, separated entrance/dump valve, separated
Spare solenoid valve, separated pressure sensor and separated working interface, so that the single channel pressure adjustment module of front axle
The single channel pressure adjustment module of brake pressure and rear axle only in control front axle service brake circuit only controls rear axle driving
Brake pressure in brake circuit.
Preferably, the second electron gas dynamic formula pressure adjusting module is configured to single channel pressure similar to first pressure adjustment module
Power adjustment module and the second entrance/discharge for relaying valve gear with second, pneumatically controlling the second relaying valve gear
Solenoid valve combination, the second spare solenoid valve, the second pressure sensor that is connect with the working outputs of second relay valve with
And the second control electronic device, the second control electronic device control entrance/discharge solenoid valve combination and the second spare solenoid valve
And the signal for representing the pressure on the second working outputs is received to adjust the second brake pressure on the second working interface.It should
Second brake pressure is then rear axle brake pressure.
Preferably, the second electron gas dynamic formula pressure adjusting module second supply interface then with independently of the first compressed air
Feeding mechanism is connected with the second compressed air supply system of third compressed air supply system.This realizes electron gas dynamic formula system
The higher safety and reliability of dynamic device.
In addition, electron gas dynamic formula brake apparatus for example further includes foot brake value transmitter, the foot brake value transmitter according to
The manipulation of foot operating mechanism and in electric channel by electric signal be input to first pressure adjustment module first control electronic device
In the second control electronic device of second pressure adjustment module, and it is in preceding axis channel that the first pneumatic type control pressure is defeated
Enter and the second pneumatic control pressure is input in the second spare solenoid valve into the first spare solenoid valve and in rear axis channel.
Sky is compressed with the third for giving first pressure adjustment module to supply compressed air together with the first compressed air supply system
Gas feeding mechanism is preferably offset in the component part in the auxiliary consumer circuit in front axle service brake circuit.Therefore, no
Additional compressed air supply system must be used as third compressed air supply system, but use anyway already existing use
In the compressed air supply system for supplying compressed air to auxiliary consumer.
According to an extended mode, pressed in a pressure adjusting module, i.e. in first pressure adjustment module and/or second
In power adjustment module, in general manner for a pressure adjusting module, the pneumatic type control interface of a relaying valve gear is not only
The control pressure of output can be combined by entrance/dump valve and the control pressure that can be exported by service valve loads.Cause
This, if the control electronic device failure in current supply arrangement or a pressure adjusting module, is arrived by springs preload
Spare solenoid valve in conducting position state is switched in the case where being not powered in the conducting position state, relays the gas of valve gear as a result,
Dynamic mode control interface is by with the control of foot brake value transmitter generated in corresponding channel (preceding axis channel or rear axis channel)
Pressure-loaded and the relay valve, which are installed on, can be based on the control pressure and is connect in the work of involved pressure adjusting module
Brake pressure is generated on mouthful.Therefore, in this case, happens is that this or all brakings time for being related to mistake or failure
The pure pneumatic control on road.
According to an alternative embodiment, first pressure adjustment module can also be arbitrary pressure adjusting module, example
As trailer control module is led to although the trailer control module is fitted without second pressure adjustment module in this case
It crosses the first compressed air supply system and third compressed air supply system and two check-valves is provided with compressed air.
The invention further relates to a kind of vehicles, are especially configured to the towing vehicle of drawbar trailer, this drags towing vehicle to have
There is electron gas dynamic formula brake apparatus stated above.
Description of the drawings
It is shown in the accompanying drawings below and is set forth in the embodiment of the present invention in the following description.Show in the accompanying drawings
Go out:
The selected parts of the schematic circuit diagram of the preferred embodiment of the electron gas dynamic formula service braking device of Fig. 1 present invention;
The schematic representation of check-valves of the Fig. 2A in ending position state, as it is preferably in the electron gas dynamic formula according to Fig. 1
In service braking device as use;
The schematic representation of the check-valves of the Fig. 2A of Fig. 2 B in open position state.
Specific implementation mode
Fig. 1 shows the schematic circuit diagram of the preferred embodiment of the electron gas dynamic formula service braking device 1 of the present invention
Selected parts.The electron gas dynamic formula service braking device 1 is arranged on towing vehicle, especially commercial car, the Vehicle structure be for
Drawbar trailer.
Herein, it is shown due to size for example in the electrical adjustment braking system (EBS) adjusted with brake pressure
The binary channels pressure adjusting module 2 and foot brake module 4 of the electron gas dynamic formula service braking device 1 of form.The binary channels pressure
Power adjustment module 2 is a kind of structural unit, and there are two independent single channel pressure adjustment module, the lists for arrangement in its shell
First pressure adjustment module 6 in channel pressure adjustment module is to adjust the front axle pressure of the brake pressure in front axle brake cylinder 8
Adjustment module and second pressure adjustment module 10 are to adjust the rear axle pressure adjusting mould of the brake pressure in rear axle checking cylinder 12
Block.
Each single channel pressure adjustment module 6,10 includes supply interface 14a, 14b, is connect with the supply interface
With the entrance/discharge solenoid valve block for entering valve 18a, 18b and dump valve 20a, 20b respectively as two/two three-way electromagnetic valves
Close 16a, 16b, combine 16a by the entrance/discharge solenoid valve, 16b pneumatically control for example in the relaying of relay valve form
Valve gear 22a, 22b, spare solenoid valve 24a, working outputs 26a, the 26b connection of 24b and relaying valve gear 22a, 22b
Pressure sensor 28a, 28b and control electronic device 30a, 30b, the control electronic device control the entrance/discharge electricity
Magnet valve combines 16a, 16b and the spare solenoid valve 24a, 24b and from pressure sensor 28a, and 28b receptions represent work output
Hold 26a, the signal of the pressure on 26b, so as to upper in the working interface 32a, 32b of involved pressure adjusting module 6,10
The mode known adjusts brake pressure.In addition, each pressure adjusting module 6,10 further includes interior between above-mentioned component and structure group
The press-in connection of the inside also will be discussed in further detail in the press-in connection in portion below.Above-mentioned component and structure group peace
In the shell 34 of binary channels pressure adjusting module 2, which is indicated by the frame surrounded with dotted line in Fig. 1.
In front axle pressure adjusting module 6, pass through internal press-in connection 36a and binary channels in input side into valve 18a
First supply interface 10 of the shell 30 of pressure adjusting module 2 connects, which passes through the first feeding pipe and the
One compressed air supply system 40 connects, which is associated with front axle and is therefore that front axle compression is empty
Gas feeding mechanism.It is disposed with first check-valve 42 in the first feeding pipe 38.On the other hand, binary channels pressure adjusting module
First supply interface 14a of 2 shell 34 is connect also by third feeding pipe 44 with third compressed air supply system 46,
It is disposed with second check-valve 48 in the third feeding pipe.The press-in connection 50a of another inside connects from the first supply of shell 30
Mouth 14a is directed to the first supply input terminal 52a of the first relaying valve gear 22a.Third compressed air supply system 46 is, for example,
For assisting consumer circuit, such as compressed air supply system in air spring circuit and being supplied with the first compressed air
Device separates or independently of first compressed air supply system.Rear axle pressure adjusting module 10 is configured similarly to front axle pressure
Adjustment module 6.
As can be obtained from Fig. 2A and 2B, two check-valves 42,48 are respectively provided with the spring by spring element 54
Force the valve closure member 58 to valve seat 56.Here, the input terminal 60 of check-valves 42,48 respectively with compressed air supply system 40,
46 connections and output end 62 are supplied interface 14a with first respectively and are connect.
Cut-off position state, in the cut-off position state, spring force that valve closure member 58 passes through spring element 54 are shown in fig. 2
It compresses valve seat 56 and therefore can not possibly occur from involved compressed air supply system 40, the 46 to the first supply interface 14a
Flowing, reason is, for example,:Pressure (supply pressure in compression gas suppling device) at input terminal 60 and output end 62
Pressure difference between the pressure (pressure of the first supply interface) at place is less than the opening pressure of check-valves 42,48.At the same time,
Fig. 2 B show conducting position state, in the conducting position state, pressure (the supply pressure in compression gas suppling device of input end 60
Power) and output end 62 at the pressure pressure of interface (first supply) between pressure difference be greater than or equal to the check-valves valve
42,48 opening pressure.Therefore, in terms of from input terminal 60 to the direction of output end 62, there are check-valves 42,48 conducting sides
To as indicated in fig. 2b by arrow.On the contrary, the output from check-valves 42,48 will not occur in principle
The compressed air of end 62 to input terminal 60 flows (cut-off direction), as shown in the arrow in Fig. 2A, because of valve closure member
58 not only through spring force and additionally also compress valve seat 56 by the pressure of output end 62, so that check-valves 42,48
There is cut-off direction and conducting direction for corresponding flow direction.
Therefore, check-valves 42,48 allow along conducting direction (from input terminal 60 to output end 62) and are meeting or exceeding
From each of described two compressed air supply systems 40,46 (in valve closure member 58 after valve seat 56 lifts) when opening pressure
A compressed air flowing in the first supply interface 14a, however, being prevented after valve closure member 58 compresses valve seat 56 along cut-off side
To (from output end to input terminal) from the first supply interface 14a to one of described two compressed air supply systems 40 or 46 or
To the compressed air flowing in two compressed air supply systems.In addition, according to Fig. 1 as it can be seen that check-valves 42,48 is ended due to it
Direction and prevent from the first compressed air supply system 40 to third compressed air supply system 46 or from third compressed air
Compressed air flowing in the 46 to the first compressed air supply system of feeding mechanism 40.
In each pressure adjusting module 6,10, into valve 18a, 18b and dump valve 20a, 20b are configured to 2/2-way
Solenoid valve and its output end connect with its input terminal and ends the connection when being not powered on when being powered.Into valve 18a,
Control signal 66a, the 66b companies that the output end of 18b passes through internal press-in connection 64a, 64b and relaying valve gear 22a, 22b
It connects.In addition, the input terminal of these control signals 66a, 66b by internal press-in connection 64a, 64b and dump valve 20a, 20b
Connection, the dump valve ends exhaust portion 68a, 68b when being not powered on to the connection of air and establish the connection in energization.
Second supply interface 14b is attached to by the second feeding pipe 72 on the second compressed air supply system 74, this
Two compressed air supply systems are associated with rear axle and are therefore rear axle compressed air supply systems.Up to the present explanation relates to
And the compressed air supply side of binary channels pressure adjusting module.
In control pressure side, for example there are two pneumatic type controls on the shell 30 of binary channels pressure adjusting module herein
Interface 76a, 76b processed.First control interface 76a of front axle pressure adjusting module 6 is attached to foot brake mould by pressure piping 78a
Block 4 be herein binary channels service brake valve pneumatic type before on axis channel 80a, and the second of rear axle pressure adjusting module 10
Control interface 76b is attached to after the pneumatic type of service brake valve by pressure piping 78b on axis channel 80b.Preceding axis channel 80a exists
Input side is attached to by supply line not shown here on the first compressed air supply system 40 and rear axis channel 80b is logical
Same unshowned supply line is crossed to be attached on the second compressed air supply system 74, second compressed air supply system with
First compressed air supply system 40 and third compressed air supply system 46 separate.
In addition, foot brake module 4 further includes electric channel 82.Therefore, if for example manipulated in the foot of foot brake pedal form
Mechanism 84 is manipulated, then 4 one side of foot brake module will represent the spare control pressure of the desired pneumatic type of driver drives vehicle braking
Power be input in preceding axis channel 80a and rear axis channel 80b and at the same time by electric channel 82 by electricity service brake request signal
It is input in the first and second electric signal interface 88a, 88b of shell 34 by Electrical signal lines 86a, 86b, described first and
Two electric signal interfaces control electronic device 30a with first in inside or are connect with the second control electronic device 30b.
Then, it is distributed according to the service brake request signal of electricity and other parameter such as axle load, controls electronic device
Two pressure adjusting modules 6,10 of 30a, 30b manipulation (or triggering), so as in the working outputs of relaying valve gear 22a, 22b
The specified braking pressure of the service brake request signal and the other parameter corresponding to the electricity is generated on 26a, 26b respectively
Power, working interface 32a, the 32b connection of the working outputs and shell 34 of the relaying valve gear.
For this purpose, entrance/dump valve combination that control electronic device 30a, the 30b manipulation of pressure adjusting module 6,10 is involved
16a, 16b correspond to be generated on pneumatic type the control signal 66a, 66b of involved relaying valve gear 22a, 22b
The control pressure of specified brake pressure.Then, relaying valve gear 22a, 22b exists according on its supply input terminal 56a, 56b
Supply pressure adjust the brake pressure on its working outputs 26a, 26b, then the working outputs pass through comprising involved
Pressure sensor 28a, 28b, internal press-in connection 90a, 90b and involved working interface 32a, 32b connection.Each
Working interface 32a, 32b are further through pressure piping 92a, 92b and the abs pressure control by control electronic device 30a, 30b electric control
Valve 94a processed, 94b connection, the abs pressure control valve can be with according to whether keeping in the presence of the brake slip not allowed, reducing
The brake pressure that is exported on involved working outputs 26a, 26b by involved relaying valve gear 22a, 22b should
Brake pressure is transferred to Pneumatic brake cylinder 8,12 uninfluencedly.
Then, pressure sensor 28a, 28b measure respectively actual brake pressure and by the actual brake pressure report to
Then control electronic device 30a, the 30b of involved pressure adjusting module 6,10, the pressure adjusting module control affiliated
Into/discharge solenoid valve combination 16a, 16b, so that actual brake pressure is adjusted to specified brake pressure.
These relayings valve gear 22a, 22b are respectively formed relay valve and respectively include double-beat drop valve 96a, 96b, the two-seater
Valve respectively includes entering valve and dump valve in known manner, wherein in valve member 98a, 98b is lifted the valve that enters from valve seat is entered
It opens when rising and is closed when valve member 98a, 98b are compressed into valve seat, the dump valve is in valve member 98a, and 98b is from discharge valve seat
It opens when lifting and is closed when valve member 98a, 98b compress discharge valve seat.Then, by the double-beat drop valve 96a, 96b into
Enter valve, can be connect with compressed air input chamber with the operating room of working outputs 26a, 26b connections, and operating room is described in
The dump valve of double-beat drop valve 96a, 96b can be connect via exhaust portion 100a, 100b with air.Then, valve gear 22a is relayed, 22b's
Compressed air input chamber supplies interface 14a, 14b connection with first or second respectively.
In addition, each relaying valve gear 22a, 22b has can be present on involved control signal 66a, 66b
Relaying the piston 102a, 102b of control pressure load.For this purpose, control signal 66a, 66b is connect with control room respectively, in described
After piston 102a, control room described in shell 104a, the 104b limit of 102b and relaying valve gear 22a, 22b.Relay piston
102a, 102b are axially moveably guided in shell 104a, 104b.
Relay piston 102a, 102b by relaying valve gear 22a, 22b shell 104a, 104b in axially moveably
The valve member 98a, 98b being guided manipulate double-beat drop valve 96a, 96b.The valve member 98a, 98b are in reverse to manipulation direction by compression spring
It is supported on the shell 104a, 104b of relaying valve gear 22a, 22b.The working method of such double-beat drop valve 96a, 96b are abundant
It is known.
Therefore, front axle service brake circuit includes:Electric channel for higher level's electron gas dynamic formula front axle service brake circuit
82;For axis channel 80a before the pneumatic type in subordinate's pneumatic type front axle service brake circuit;Front axle pressure adjusting module 6, especially
It is passed with the first relaying valve gear 22a, the first entrance/discharge solenoid valve combination 16a, the first spare solenoid valve 24a, first pressure
Sensor 28a;The checking cylinder 8 and institute of first compressed air supply system 40 and third compressed air supply system 46 and front axle
The press-in connection of category.Abs pressure control valve 94a on front axle is optional.
Rear axle service brake circuit includes:Electric channel 82 for higher level's electron gas dynamic formula rear axle service brake circuit;With
The axis channel 80a after the pneumatic type in subordinate's pneumatic type rear axle service brake circuit;Rear axle pressure adjusting module 10, especially has
Second relaying valve gear 22b, the second entrance/discharge solenoid valve combination 16b, the second spare solenoid valve 24b, second pressure sensor
28b;The checking cylinder 12 and affiliated press-in connection of second compressed air supply system 74 and rear axle.ABS pressures on rear axle
Force control valve 94b is equally optional.
(front axle pressure adjusting module 6 and rear axle pressure adjusting module 10 are summarised in the bilateral to binary channels pressure adjusting module 2
In road pressure adjusting module) for example it is arranged on the vehicle frame of towing vehicle in rear axle region.Alternatively, the binary channels pressure tune
Section module 2 can also be substantially centrally arranged between front axle and rear axle on vehicle frame.
In this context, the working method of electron gas dynamic formula service braking device 1 is as follows:
In the case of compressed air feedway and electric installation or intact electronic device, foot brake plate 84 is being manipulated
When, the service brake request signal of electricity is on the one hand generated in the electric channel 82 of foot brake module 4 and is conducted to control electronics
Device 30a, 30b, the control electronic device according to the other parameter of the service brake request signal and possibility of the electricity, for example
Axle load distributes, and the signal for representing specified brake pressure is input in involved entrance/dump valve combination 16a, 16b.By
It is distributed in determining axle load, so the specified brake pressure of front axle for example can be different from the specified brake pressure of rear axle.
Concurrently with this, control pressure (front axle control is generated in two channels of the service brake valve of foot brake module 4
Pressure, rear axle control pressure) and be input in pneumatic type the control interface 76a, 76b of binary channels pressure adjusting module 2,
In, involved control pressure is directed to involved spare solenoid valve 24a, on the input terminal of 24b, the spare solenoid valve by
The control pressure is prevented to reach involved relaying valve gear 22a, the control signal of 22b in the cut-off position state of its energization
66a,66b。
It carries out supplying from the first compressed air supply system 40 and third compressed air in the pressure adjusting module 6 of front axle
Parallel supply of the device 46 to the first supply interface 14a.Here, two check-valves 42,48 enter in its conduction position and
Allow on its conducting direction from two compressed air supply systems 40, the compressed air flowing of the 46 to the first supply interface 14a,
For supplying the first entrance/discharge solenoid valve relaying valve gears of combination 16a and first 22a.Involved control electronic device
Then entrance/discharge solenoid valve that 30a, 30b manipulate involved pressure adjusting module 6,10 combines 16a, 16b, so as in institute
The control pressure corresponding to specified brake pressure is generated on the control signal 66a, 66b of the relaying valve gear 22a, 22b that are related to.
The control pressure is present in the control room of involved relaying valve gear 22a, 22b and will relay piston 102a, and 102b exists
It is pushed down in Fig. 1, thus valve member 98a, 98b is moved down and the dump valve of double-beat drop valve 96a, 96b are closed and beaten into valve
It opens.As a result, on the one hand according to the corresponding controlled opening cross-section for entering valve, present in compressed air input chamber, from institute
The compressed air supply system 40,46 being related to 74 or attracts pressure from involved compressed air supply system 40,46,74
Air reaches the working outputs 26a, 26b of involved relaying valve gear 22a, 22b and there shape under supply pressure
At actual brake pressure, the actual brake pressure is by involved pressure sensor 28a, 28b measurement and feeds back to involved
Control electronic device 30a, 30b.In the case where actual brake pressure and specified brake pressure deviate, grasped in calibration meaning
The involved entrance of control/discharge solenoid valve combines 16a, 16b.Then, the downstreams working interface 32a, 32b are arranged in by two
Abs pressure control valve 94a, 94b, specified brake pressure enter the pneumatic brake cylinder 8 of front axle or the pneumatic brake cylinder of rear axle
In 12.If the brake slip not allowed is detected during service brake, then manipulation abs pressure control valve 94a, 94b, are used
It is kept in pressure reduction, pressure or pressure is connected, until there is the brake slip allowed.
If current supply arrangement either a control electronic device 30a or 30b failure or two control electronic devices
30a, 30b fail, then involved entrance/discharge solenoid valve combines 30a, 30b no longer gives relaying valve gear 22a, 22b's
Control signal 66a, 66b provide control pressure.For this purpose, involved relaying valve gear 22a, 22b are switched to when being not powered on
It is in the state of position and to allow involved control pressure (rear axle control pressure or front axle control pressure) to act on involved
On the control signal 66a, 66b for relaying valve gear 22a, 22b.Then, which is responsible for:In the checking cylinder 8 of front axle
Or there is in the checking cylinder 12 of rear axle or on both axes brake pressure, however adjusted without brake pressure.
If in the first feeding pipe 38 between the first compressed air supply system 40 and first supply interface 14a or
Person is in the third feeding pipe 44 that third compressed air supply system 46 and first supplies between interface 14a or also in the first pressure
It is leaked in contracting air supply device 40 or third compressed air supply system 46 itself, then can be by corresponding intact
Feeding pipe 38,44 and corresponding intact compressed air supply system 40,46 carry out the supply of the first supply interface 14a, to
So that front axle pressure adjusting module 6 keeps completely intact.On the other hand, check-valves 42,48 cut-off direction prevent for example to compress
Air is flowed into the first compressed air supply system 40 leaked from the intact supplement of third compressed air supply system 46
In and be thus drained.
It should be understood that described two check-valves 42,48 and the third compressed air supply system 46 may be set to be use
In rear axle pressure adjusting module 10 and with the second of the rear axle pressure adjusting module the supply interface 14b it is correspondingly connected.
Reference numerals list
1 service braking device
2 binary channels pressure adjusting modules
4 foot brake modules
6 first pressure control modules
8 front axle brake cylinders
10 second pressure control modules
12 rear axle checking cylinders
14 supply interfaces
16 entrance/discharge solenoid valve combination
18 enter valve
20 dump valves
22 relaying valve gears
24 spare solenoid valves
26 working outputs
28 pressure sensors
30 control electronic devices
32 working interfaces
34 shells
36 press-in connections
38 first feeding pipes
40 first compressed air supply systems
42 first check-valves
44 third feeding pipes
46 third compressed air supply systems
48 second check-valves
50 press-in connections
52 supply input terminals
54 spring elements
56 valve seats
58 valve closure members
60 input terminals
62 output ends
64 press-in connections
66 control signals
68 exhaust portions
72 second feeding pipes
74 second compressed air supply systems
76 control interfaces
78 pressure pipings
80 pneumatic type channels
82 electric channels
84 foot operating mechanisms
86 signal lines
88 signaling interfaces
90 press-in connections
92 pressure pipings
94 abs pressure control valves
96 double-beat drop valves
98 valve members
100 exhaust portions
102 relaying pistons
104 shells
Claims (10)
1. a kind of electron gas dynamic formula brake apparatus (1), has
A) the first electron gas dynamic formula pressure adjusting module (6), the first electron gas dynamic formula pressure adjusting module have in first
After valve gear (22a), pneumatically control this first relaying valve gear (22a) the first entrance/discharge solenoid valve combination (16a),
First spare solenoid valve (24a), first connect with the first working outputs (26a) of the first relaying valve gear (22a)
Pressure sensor (28a) and the first control electronic device (30a), the first control electronic device control first entrance/
Discharge solenoid valve, which combines (16a) and the first spare solenoid valve (24a) and receives, represents first working outputs
The signal of pressure on (26a) is to adjust the first brake pressure on first working outputs (26a);
B) the first pressure adjustment module (6), with it is described first relay valve gear (22a) first supply input terminal
(52a) and the first supply interface (14a) for entering valve (18a) and connecting that (16a) is combined with the entrance/discharge solenoid valve,
Wherein,
C) the first working outputs (26a) of the first relaying valve gear (22a) and the first pressure adjustment module (6)
First working interface (32a) connects, which directly or indirectly connects at least one first Pneumatic brake cylinder (8)
It connects, and wherein,
D) the first supply interface (14a) of the first pressure adjustment module (6) is supplied with two mutually independent compressed airs
At least one of device (40,46), i.e. the first compressed air supply system (40) and third compressed air supply system (46)
Connection, which is characterized in that
E) the first supply interface (14a) is filled by least one first check-valve (42) and first compressed air supply
(40) are set to connect and connect with the third compressed air supply system (46) by least one second check-valve (48),
In,
F) check-valves (42,48) respectively includes at least one spring force pressure by least one spring element (54) and supports valve
The valve closure member (58) of seat (56) and allow from the pressure along conducting direction when valve closure member (56) is lifted from valve seat (56)
In contracting air supply device (40,46) each or simultaneously from two compressed air supply systems (40,46) to described
The compressed air flowing of one supply interface (14a), however prevented along cut-off direction when valve closure member (58) compresses valve seat (56)
It is compressed one of from the first supply interface (14a) to described two compressed air supply systems (40,46) or to the two
The compressed air of air supply device (40,46) flows and from first compressed air supply system (40) to the third
Compressed air supply system (46) supplies dress from the third compressed air supply system (46) to first compressed air
Set the compressed air flowing of (40).
2. brake apparatus described in accordance with the claim 1, which is characterized in that the first pressure adjustment module (6) is front axle row
Front axle pressure adjusting module in vehicle brake circuit, wherein at least two of first working interface (32a) and front axle are pneumatic
Formula checking cylinder (8) directly or indirectly connects, wherein first compressed air supply system (40) is the front axle driving system
The front axle compressed air supply system in dynamic circuit.
3. brake apparatus according to claim 2, which is characterized in that the first electron gas dynamic formula pressure adjusting module
(6) with the second electron gas dynamic formula pressure adjusting module (10) binary channels pressure adjusting module is mounted on together as structural unit
(2) in, wherein the second pressure adjustment module (10) be the rear axle pressure adjusting module in rear axle service brake circuit and
The second working interface (32b) of the second pressure adjustment module (10) is straight at least two Pneumatic brake cylinders (12) of rear axle
It connects or connects indirectly.
4. brake apparatus described in accordance with the claim 3, which is characterized in that the second electron gas dynamic formula pressure adjusting module
(10) the second entrance/discharge for relaying valve gear (22b) with second, pneumatically controlling the second relaying valve gear (22b)
Solenoid valve combines (16b), the second spare solenoid valve (24b), the second working outputs with second relay valve (22b)
The second pressure sensor (28b) of (26b) connection and the second control electronic device (30b), the second control electronic device control
It makes second entrance/discharge solenoid valve combination (16b) and the second spare solenoid valve (24b) and reception represents described the
The signal of pressure on two working outputs (26b) is to adjust the second brake pressure on second working interface (26b).
5. brake apparatus according to claim 4, which is characterized in that the second electron gas dynamic formula pressure adjusting module
(10) second supplies interface (14b) and independently of first compressed air supply system (40) and the third compressed air
The second compressed air supply system (74) of feeding mechanism (46) connects.
6. according to the brake apparatus described in claim 4 or 5, which is characterized in that the brake apparatus includes foot brake value transmitter
(4), the foot brake value transmitter is at least defeated by electric signal in electric channel (82) according to the manipulation of foot operating mechanism (84)
Enter into the first control electronic device (30a) and the second control electronic device (30b) and before pneumatic type in axis channel (80a)
First pneumatic type control pressure is input in the first spare solenoid valve (24a) and in rear axis channel (80b) by the second gas
Dynamic control pressure inputs in the second spare solenoid valve (24b).
7. according to the brake apparatus described in any one of preceding claims, which is characterized in that the third compressed air supply
Device (46) is the component part different from the auxiliary consumer circuit in front axle service brake circuit.
8. according to the brake apparatus described in any one of preceding claims, which is characterized in that in pressure adjusting module (6,10)
In, the pneumatic type control signal (66a, 66b) of relaying valve gear (22a, 22b) is not only able to by by entrance/discharge solenoid valve
The control pressure of combination (16a, 16b) output and the control pressure load that can be exported by spare solenoid valve (24a, 24b).
9. according to the brake apparatus described in any one of preceding claims, which is characterized in that the first pressure adjustment module
It is trailer control module.
10. a kind of vehicle is especially configured to the towing vehicle for drawbar trailer, have according to any in preceding claims
Brake apparatus (1) described in.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
DE102015117284.4 | 2015-10-09 | ||
DE102015117284.4A DE102015117284A1 (en) | 2015-10-09 | 2015-10-09 | Electro-pneumatic braking device with a connected via two check valves with two compressed air supplies pressure control module |
PCT/EP2016/072967 WO2017060128A1 (en) | 2015-10-09 | 2016-09-27 | Electropneumatic brake device comprising a pressure-regulating module connected to two compressed-air supplies by means of two check valves |
Publications (2)
Publication Number | Publication Date |
---|---|
CN108367741A true CN108367741A (en) | 2018-08-03 |
CN108367741B CN108367741B (en) | 2020-11-20 |
Family
ID=57047207
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201680071597.6A Active CN108367741B (en) | 2015-10-09 | 2016-09-27 | Electropneumatic brake device with pressure regulating module connected to two compressed air supplies by two non-return valves |
Country Status (4)
Country | Link |
---|---|
EP (1) | EP3359432B1 (en) |
CN (1) | CN108367741B (en) |
DE (1) | DE102015117284A1 (en) |
WO (1) | WO2017060128A1 (en) |
Families Citing this family (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE102018102764A1 (en) | 2018-02-07 | 2019-08-08 | Haldex Brake Products Aktiebolag | Brake system for a commercial vehicle, compressed air treatment unit and use of a compressed air conditioning unit |
EP3787943B1 (en) | 2018-05-03 | 2022-06-22 | Volvo Truck Corporation | Redundant braking unit for a braking system and system using same |
DE102018114639A1 (en) * | 2018-06-19 | 2019-12-19 | Knorr-Bremse Systeme für Nutzfahrzeuge GmbH | Parking brake device for a motor vehicle |
WO2019170925A2 (en) | 2019-06-03 | 2019-09-12 | Haldex Brake Products Aktiebolag | Electropneumatic brake system for a utility vehicle and utility vehicle comprising an electropneumatic brake system |
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- 2016-09-27 WO PCT/EP2016/072967 patent/WO2017060128A1/en active Application Filing
- 2016-09-27 CN CN201680071597.6A patent/CN108367741B/en active Active
- 2016-09-27 EP EP16775178.3A patent/EP3359432B1/en active Active
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Also Published As
Publication number | Publication date |
---|---|
DE102015117284A1 (en) | 2017-04-13 |
EP3359432B1 (en) | 2020-05-20 |
WO2017060128A1 (en) | 2017-04-13 |
CN108367741B (en) | 2020-11-20 |
EP3359432A1 (en) | 2018-08-15 |
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